Design Airspace (Routes, Approaches and Holds) Module 11 Activity 7 European Airspace Concept Workshops for PBN Implementation
Design in Context TFC Where does the traffic come from? And when? RWY Which Runway(s)? SUR NAV Is there Radar? Which equipage? How many aircraft? Airspace Concept Workshop 2
Design in Context Methodology STEPS Airspace Concept Workshop 3
Competing Interests Airspace Concept Workshop 4
Routes Airspace Concept Workshop 5
Terminal Routes Routes in Terminal Airspace link Raw demand Runway in use ATS Routes of the ARN Airspace Concept Workshop 6
Different Kinds of IFP Open Path Closed Path Airspace Concept Workshop 7
SID/STAR Dependence on RWY (1) RWY orientation is given Direction of RWY in use depends on wind Wind Wind Airspace Concept Workshop 8
SID/STAR Dependence on RWY (2) Different set of SIDs and STARs for different Runway in use Wind Airspace Concept Workshop 9
Seasonal Effect (1) Demand and route placement can vary for different seasons Summer Airspace Concept Workshop 10
Seasonal Effect (2) Different set of SIDs and STARs per season Winter Airspace Concept Workshop 11
Good Design Practice Segregate Arrivals from Departures Both Laterally and Vertically Airspace Concept Workshop 12
Good Design Practice Segregation of Routes and Entry/Exit point A D D D AD X D D R1.1 R1.1 Minimise the number of crossing points Plan for vertical separation Arrival 30NM from Touchdown Departure 7NM from Take-Off X X X X R1.2 (Graph 5-1) R1.2 (Graph 5-1) Airspace Concept Workshop 13 13
Good Design Practice SAMPLE SAMPLE CHART ONLY: SIMILAR GRAPHS SHOULD BE DEVELOPED FOR EACH IMPLEMENTATION Airspace Concept Workshop DEPENDING ON FLEET 14 14
25 Good Design Practice Fix the same Exit/Entry points for different RWY configurations (handoff between ACC and APP should not change with RWY configuration) D D D TA boundary D D D TA boundary A A R2.1 RWY27 R2.1 07 25 07 RWY09 Airspace Concept Workshop 15 15
Good Design Practice Gradually converge inbound flows A AX Group similar inbound flows in Entry Gates R3 R3 ENTRY GATE R3 Airspace Concept Workshop 16 16
Conventional SID Limitations: Inflexible SID/STAR design: constraint to airspace optimisation Track accuracy performance cannot be stipulated Inconsistent trackkeeping performance Require the use of VOR/DME and/or NDB Advantages: All aircraft operating under IFR are suitably equipped Defined by NAVAIDs Airspace Concept Workshop 17
The Benefits of RNAV Airspace Concept Workshop 18
RNAV Departures at Atlanta USA BEFORE AFTER Slide from ICAO PBN Seminar Airspace Concept Workshop 19
07 07 07 07 Good Design Practice XXXXX High Complexity 25 Minimise Crossing Complexity 25 25 Managed Complexity 25 Airspace Concept Workshop 20
Safety Assessment for Route Spacing GLOBAL ASSESSMENT (ICAO) REGIONAL ASSESSMENT STATE ASSESSMENT LOCAL IMPLEMENTATION ASSESSMENT Key Assessment Scope Portion of Assessment to be completed at more detailed level (below). Airspace Concept Workshop 21 21
Route Spacing Airspace Concept Workshop 22
Route Spacing Generic model used to determine separation and ATS Route spacing Airspace Concept Workshop 23 23
Route Spacing NAVIGATION Performance Based Concept Navigation Application EXPOSURE TO RISK INTERVENTION PBN Navigation Specification NAVAID Infrastructure Operational Error Route Configuration Traffic Density Communication Surveillance ATC Procedures and Tools Determination of separation minima (1) for tactical use without ATC Surveillance Determination of separation minima (1) for tactical use with ATC Surveillance Determination of Route Spacing without ATC Surveillance (2) (2) & (3) Determination of Route Spacing with ATC Surveillance Relevant; largely irrelevant; (1) In context, separation minima based on Navaid or Navigation Sensor or PBN; (2) traffic density = single aircraft pair; (3) separation minima determined as a function of performance of ATC surveillance system. Airspace Concept Workshop 24 24
Route Spacing Summary for ECAC Radar Environment Interpreted results of various EUROCONTROL route spacing studies. The route spacing advantages of Advanced RNP are contrasted to those of P-RNAV and B-RNAV. Parallel Routes / based on Same Direction Opposite Direction Other Spacing on turning segments Advanced RNP P-RNAV* B-RNAV En Route Terminal En Route Terminal En Route 7 NM 7 NM 9 NM 8 NM As above using FRT en-route and RF for SIDs/STARs Larger than above because no FRT 16.5 NM 18 NM 10-15 NM with increased ATC intervention rates Much larger than above because of no automatic leg change Assumption is that all aircraft in same ATC sector * In 2000, a spacing of 7 NM was considered possible in a specific study undertaken for the Paris London tracks south of CBA 1. This finding does not suggest that 7 NM spacing is generally possible with P-RNAV. This particular spacing is to be seen in the context of the Paris London tracks and depends on the situation studied and associated assumptions viz. the specifics of the route configuration, the navigation performance of the aircraft operating on those tracks at the traffic characteristics, etc. Airspace Concept Workshop 25
PANS-ATM Route Spacing Procedural Terminal for PBN 90 Up to 400 Movements Per day 45 A/C 2 7 NM Runway Good for: RNAV1 B-RNP1 RNP APCH RNP (AR) APCH Airspace Concept Workshop 26 26
Good Design Practice Holds H2 A X Terminal Airspace Boundary H1 H1 A H1 Merging of routes at holding point may be too complex. Terminal Airspace Boundary A D X H.1 R1.2 (Graph 5-1) Terminal Airspace Boundary H2 Terminal Airspace Boundary A H2 Terminal Airspace Boundary A Airspace Concept Workshop 27 27
Continuous Descent Operations Establish on the Instrument Establish on the Landing Instrument System Landing System Extended «Continuous Conventional» level segment Descent Approach at Operation Approach low level profiles Profiles Idle Descent Area of environmental benefits -5 to -30% From Higher «Conventional Noise» low Approach level flight Profiles Reduction of -10 to -30% Fuel burn and CO 2 emissions Airspace Concept Workshop 28
CDO Definition Continuous Descent Operations is an aircraft operating technique in which an arriving aircraft descends from an optimal position with minimum thrust and avoids level flight to the extent permitted by the safe operation of the aircraft and compliance with published procedures and ATC instructions. A flying (pilot) technique facilitated by Air Traffic It is not an ATC procedure Airspace Concept Workshop 29
Benefit Percentage of CD achieved Altitude Profile Capacity DTG implicit Procedure Standard Arrival Route using Precision area NAVigation (RNAV1) Radar Approach controllers offer estimate(s) of DTG 60 to 80% 100% 5 to 10% In low traffic density During busy periods 80% From higher (Ideally Top of Descent) From lower altitude Ideal Hungry Mix of both optimises the benefits of CDO Less OK hungry DTG explicit Provision of Distance To Go (DTG) Central Technique Airspace Concept Workshop 30
Point Merge System (PMS) Integrated sequence Merge point Envelope of possible paths Arrival flow Arrival flow Sequencing legs (each leg arcs the same distance from the merge point) Point Merge System - example with two inbound flows Airspace Concept Workshop 31 31
Scenario Talk-Through (1/5) M STRUCTURE A B Scenario talk-through for Grey, Green, Gold and Blue aircraft Airspace Concept Workshop 32
Scenario Talk-Through (2/5) 2 Initial situation with a busy flow of traffic to the merge point Airspace Concept Workshop 33
Scenario Talk-Through (3/5) 3 Grey heavy jet cleared direct to the merge point. Controller determines when to issue the Direct to merge point instruction to the Gold aircraft to ensure that the required WTC spacing behind the preceding aircraft will be achieved. Airspace Concept Workshop 34
Scenario Talk-Through (4/5) 4 Controller issues the Turn left direct to merge point instruction to the Gold aircraft using the range ring arcs to assess the appropriate WTC spacing from the Grey aircraft. Airspace Concept Workshop 35
Scenario Talk-Through (5/5) 5 The same technique is repeated for the Green aircraft and subsequently for the Blue aircraft once the Green aircraft passes the next Range Ring Airspace Concept Workshop 36
Configurations Tested (1/2) Merge point Straight sequencing legs Segmented sequencing legs Common point Merge point 3 flows, with 2 sequencing legs of same direction Dissociated sequencing legs Airspace Concept Workshop 37
Configurations Tested (2/2) IAF 1 IAF 2 IAF 1 FAF IAF 2 FAF1 IAF 3 IAF 4 FAF2 IAF 4 IAF 1 IAF 3 IAF 2 FAF IAF 4 IAF 3 Airspace Concept Workshop 38
Example with 36 arrivals per hour on each runway Airspace Concept Workshop 39
Point Merge - Norway Airspace Concept Workshop 40 40
Lessons Learned Turn Anticipation: variable for ambient conditions, altitude, angle of turn, phase of flight, avionics, and aircraft Airspace Concept Workshop 41
Impact of Turn Performance RNAV 5 in en route without FRT Assumptions: FL340; 655kts ground speed (includes wind); ISA+10 Minimum bank angle applied (5 ) within max turn initiation distance of 20NM from waypoint Assumes a ±2.5 NM along track error (B-RNAV with GNSS) Assumes a fly-by turn at the waypoint (B-RNAV also allows flyover although few aircraft systems expected to employ it) This is just the nominal track and takes no account of across track error. Suggest adding route spacing value and including VOR fly-over figures for track on inside of turn. Airspace Concept Workshop 42 42
RNAV 5 Airspace Concept Workshop 43 43
RNAV 5 Airspace Concept Workshop 44 44
RNAV 5 Airspace Concept Workshop 45 45
Sample Checklist: Routes and Holds Airspace Concept Workshop 46
Questions? Now its your turn: 3 Hours to: Develop STARs/SIDs/HOLDs Both teams present results and provide rationale tomorrow Airspace Concept Workshop 47